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Rescaling the complex network of low-temperature plasma chemistry through graph-theoretical analysis

Tomoyuki Murakami, Osamu Sakai

2020Plasma Sources Science and Technology24 citationsDOIOpen Access PDF

Abstract

Abstract We propose graph-theoretical analysis for extracting inherent information from complex plasma chemistry and devise a systematic way to rescale the network under the following key criteria: (1) maintain the scale-freeness and self-similarity in the network topology and (2) select the primary species considering its topological centrality. Network analysis of reaction sets clarifies that the scale-freeness emerging from a weak preferential mechanism reflects the uniqueness of plasma-induced chemistry. The effect of chemistry rescaling on the dynamics and chemistry of the He + O 2 plasma is quantified through numerical simulations. The present chemical compression dramatically reduces the computational load, whereas the concentration profiles of reactive oxygen species (ROS) remain largely unchanged across a broad range of time, space and oxygen admixture fraction. The proposed analytical approach enables us to exploit the full potential of expansive chemical reaction data and would serve as a guideline for creating chemical reaction models.

Topics & Concepts

UniquenessExpansiveGraphCentralityComputer scienceNetwork analysisChemical similarityChemistryChemical reactionPlasmaStatistical physicsChemical physicsTheoretical computer scienceMathematicsPhysicsThermodynamicsCombinatoricsStructural similarityArtificial intelligenceBiochemistryCompressive strengthQuantum mechanicsMathematical analysisComplex Network Analysis TechniquesCO2 Reduction Techniques and CatalystsProtein Structure and Dynamics
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